Regis B. Kelly

Storage and Release of Neurotransmitters

Because synaptic vesicles and secretory granules are simple in composition and easy to purify, many of their protein components have been identified and often sequenced. Attempts are underway to link the small number of membrane proteins to the small number of functions the vesicles perform. The discovery of sequence homologies has helped greatly with this. In addition, techniques that have begun to prove successful involve microinjection, identification of proteins that bind synaptic vesicle proteins, DNA transfection into cells and oocytes, and more recently, in vitro reconstitution of exocytosis, endocytosis, and vesicle biogenesis. Advances in the latter areas have been strongly influenced by the breakthroughs in our knowledge of membrane traffic in nonneuronal cells. The budding reactions involved in making synaptic vesicles and secretory granules resemble in many ways the generation of carrier vesicles from the ER and the Golgi complex. Finally, exocytosis in neurons may closely resemble fusion of carrier vesicles with target organelles in nonneuronal cells, using complexes of peripheral membrane proteins, GTP hydrolysis, and integral membrane proteins with fusogenic domains. The usefulness of in vitro reconstitution, reverse genetics, and the parallels with better understood systems compensates in part for a major weakness in the field, namely the difficulty in obtaining viable mutants that are defective in the storage and release of secretory vesicle content.

A Function for the AP3 Coat Complex in Synaptic Vesicle Formation from Endosomes

Synaptic vesicles can be coated in vitro in a reaction that is ARF-, ATP-, and temperature-dependent and requires synaptic vesicle membrane proteins. The coat is largely made up of the heterotetrameric complex, adaptor protein 3, recently implicated in Golgi-to-vacuole traffic in yeast. Depletion of AP3 from brain cytosol inhibits small vesicle formation from PC12 endosomes in vitro. Budding from washed membranes can be reconstituted with purified AP3 and recombinant ARF1. We conclude that AP3 coating is involved in at least one pathway of small vesicle formation from endosomes.

Two distinct intracellular pathways transport secretory and membrane glycoproteins to the surface of pituitary tumor cells

The pituitary cell line, AtT-20, synthesizes adrenocorticotropic hormone (ACTH) as a glycoprotein precursor that is cleaved into mature hormones during packaging into secretory granules. The cells also produce an endogenous leukemia virus (MuLV) that is glycosylated after translation similar to the glycosylation of the ACTH precursor. Our evidence suggests that the envelope glycoprotein and some precursor ACTH get to the cell surface in a vesicle different from the mature ACTH secretory granule. Viral glycoproteins and ACTH precursor are released from the cells much sooner after synthesis than mature ACTH. Isolated secretory granules do not contain significant amounts of the envelope glycoprotein or ACTH precursor. Exposing cells to 8Br-cAMP stimulates release of mature ACTH four to five fold, but has little effect on the release of the ACTH precursor or the viral glycoproteins. We propose that the viral glycoproteins and some of the ACTH precursor are transported by a constitutive pathway, while mature ACTH is stored in secretory granules where its release is enhanced by stimulation.

Expressing a human proinsulin cDNA in a mouse ACTH-secreting cell. Intracellular storage, proteolytic processing, and secretion on stimulation

The AtT-20 cell line, derived from the mouse anterior pituitary, synthesizes an adrenocorticotropic hormone (ACTH) precursor, proteolytically processes it to mature ACTH, stores it in secretory granules, and releases mature ACTH on stimulation with a secretagogue. A cDNA for human proinsulin inserted downstream from the SV40 early promoter in an SV40-pBR322 recombinant vector was introduced into AtT-20 cells. The stably transformed cell line, AtT-20ins4b/1, stores immunoreactive insulin, proteolytically processes proinsulin to smaller fragments, and on stimulation with secretagogues releases insulin-like material, not proinsulin, into the medium. Similarly transformed fibroblast L-cells secrete only proinsulin; they do not store it, and their secretion rate is unaffected by secretagogues. The transport mechanism for precursor ACTH thus appears to recognize other prohormones.

SH3-domain-containing proteins function at distinct steps in clathrin-coated vesicle formation

Several SH3-domain-containing proteins have been implicated in endocytosis by virtue of their interactions with dynamin; however, their functions remain undefined. Here we report the efficient reconstitution of ATP-, GTP-, cytosol- and dynamin-dependent formation of clathrin-coated vesicles in permeabilized 3T3-L1 cells. The SH3 domains of intersectin, endophilin I, syndapin I and amphiphysin II inhibit coated-vesicle formation in vitro through interactions with membrane-associated proteins. Most of the SH3 domains tested selectively inhibit late events involving membrane fission, but the SH3A domain of intersectin uniquely inhibits intermediate events leading to the formation of constricted coated pits. These results suggest that interactions between SH3 domains and their partners function sequentially in endocytic coated-vesicle formation.

Dap160, a neural-specific Eps15 homology and multiple SH3 domain-containing protein that interacts with Drosophila dynamin.

The discovery of overlapping hot spots of dynamin (Estes, P. S., Roos, J., van der Bliek, A., Kelly, R. B., Krishnan, K. S., and Ramaswami, M. (1996) J. Neurosci. 16, 5443–5456) and the heterotetrameric adaptor 2 complex (Gonzalez-Gaitan, M., and Jäckle, H. (1997)Cell 88, 767–776) in Drosophila nerve terminals led to the concept of zones of active endocytosis close to sites of active exocytosis. The proline-rich domain of Drosophiladynamin was used to identify and purify a third component of the endocytosis zones. Dap160 (dynamin-associated protein 160 kDa) is a membrane-associated, dynamin-binding protein of 160 kDa that has four putative src homology 3 domains and an Eps15 homology domain, motifs frequently found in proteins associated with endocytosis. The binding capacities of the four putative src homology 3 domains were examined individually and in combination and shown to bind known proteins that contained proline-rich domains. Each binding site, however, was different in its preference for binding partners. We suggest that Dap160 is a scaffolding protein that helps anchor proteins required for endocytosis at sites where they are needed in the Drosophilanerve terminal.

Dap160/Intersectin Scaffolds the Periactive Zone to Achieve High-Fidelity Endocytosis and Normal Synaptic Growth

Dap160/Intersectin is a multidomain adaptor protein that colocalizes with endocytic machinery in the periactive zone at the Drosophila NMJ. We have generated severe loss-of-function mutations that eliminate Dap160 protein from the NMJ. dap160 mutant synapses have decreased levels of essential endocytic proteins, including dynamin, endophilin, synaptojanin, and AP180, while other markers of the active zone and periactive zone are generally unaltered. Functional analyses demonstrate that dap160 mutant synapses are unable to sustain high-frequency transmitter release, show impaired FM4-64 loading, and show a dramatic increase in presynaptic quantal size consistent with defects in synaptic vesicle recycling. The dap160 mutant synapse is grossly malformed with abundant, highly ramified, small synaptic boutons. We present a model in which Dap160 scaffolds both endocytic machinery and essential synaptic signaling systems to the periactive zone to coordinately control structural and functional synapse development.

Intermediates in synaptic vesicle recycling revealed by optical imaging of Drosophila neuromuscular junctions

We show that uptake and release of the styryl dye FM1-43 may be used to monitor synaptic vesicle exocytosis and recycling at Drosophila larval neuromuscular junctions. At Drosophila nerve terminals, FM1-43 specifically labels subsynaptic domains enriched in synaptotagmin, in a manner that requires Ca2+, membrane depolarization, and shibire (shi) function. Endocytosis rates, very low in unstimulated synapses, are induced severalfold by the exocytosis of synaptic vesicles. Using shi(ts)1 mutant synapses to separate synaptic vesicle fusion and recycling temporally, we show that recycling events subsequent to the shi block do not require extracellular Ca2+. We suggest that two distinct intermediate stages in vesicle recycling may be trapped and analyzed at Drosophila neuromuscular junctions.

A TARGETING SIGNAL IN VAMP REGULATING TRANSPORT TO SYNAPTIC VESICLES

VAMP is a synaptic vesicle membrane protein required for fusion. Synaptic vesicle targeting was measured for mutants of an epitope-tagged form of VAMP in transfected PC12 cells. A signal within a predicted amphipathic alpha helix is essential for targeting to synaptic vesicles. Cellubrevin, a nonneural VAMP homolog, contains this signal and is also targeted to synaptic vesicles. Amino acid substitutions within the synaptic vesicle targeting signal either enhance or inhibit sorting of VAMP to synaptic vesicles, but do not affect the ability of VAMP to form complexes with syntaxin and SNAP-25.

Traffic of Dynamin within Individual Drosophila Synaptic Boutons Relative to Compartment-Specific Markers

Presynaptic terminals contain several specialized compartments, which have been described by electron microscopy. We show in an identified Drosophila neuromuscular synapse that several of these compartments—synaptic vesicle clusters, presynaptic plasma membrane, presynaptic cytosol, and axonal cytoskeleton—labeled by specific reagents may be resolved from one another by laser scanning confocal microscopy. Using a panel of compartment-specific markers andDrosophila shibirets1 mutants to trap an intermediate stage in synaptic vesicle recycling, we have examined the localization and redistribution of dynamin within single synaptic varicosities at the larval neuromuscular junction. Our results suggest that dynamin is not a freely diffusible molecule in resting nerve terminals; rather, it appears localized to synaptic sites by association with yet uncharacterized presynaptic components. Inshits1 nerve terminals depleted of synaptic vesicles, dynamin is quantitatively redistributed to the plasma membrane. It is not, however, distributed uniformly over presynaptic plasmalemma; instead, fluorescence images show “hot spots” of dynamin on the plasma membrane of vesicle-depleted nerve terminals. We suggest that these dynamin-rich domains may mark the active zones for synaptic vesicle endocytosis first described at the frog neuromuscular junction.